Lipid issue are the expansive term for variations from the norm of cholesterol and triglycerides. Lipid variations from the norm are connected with an expanded danger for vascular illness, and particularly heart assaults and strokes. Anomalies in lipid issue are a mix of hereditary inclination and in addition the way of dietary admission. Numerous lipid issue are connected with being overweight. Lipid issue might likewise be connected with different sicknesses including diabetes. There is gathering prove that administration of cholesterol and triglyceride issue is connected with the lessened danger for heart assaults and strokes.

Today 66% of grown-ups and about 33% of youngsters battle with overweight and obesity. If heftiness rates stay reliable, by 2030, 51 percent of the populace will be obese. Twenty years prior, no state had a stoutness rate above 15 percent. Today there are 41 states with stoutness rates more than 25 percent, as indicated by the Trust for Europe’s Health. Following 1980, the rate of weight in kids and young people has practically tripled. 72% of more established men and 67% of more seasoned ladies are currently overweight or stout. Heftiness is connected to more than 60 perpetual illnesses. By European Association for the Study of Obesity, 482,000 Europeans kick the bucket of tumor every year, around 33% of these growth passings are connected to overabundance body weight, poor sustenance and/or physical idleness. More than 75 percent of hypertension cases are specifically connected to stoutness. Roughly 66% of Europe grown-ups with sort 2 diabetes are overweight or have heftiness.

Sessions/Tracks

ConferenceSeries Ltd welcomes every one of the members from everywhere throughout the world to join '3rd International Conference Lipid Science and Technology' amid December 11-12, 2017 in Rome, Italy which incorporates brief keynote presentations, Oral talks, Poster presentations and Exhibitions.

Lipids 2017 Conference is an unquestionable requirement to join as it will give an inside and out perspective of world-class, interdisciplinary examination dialog from fundamental science scientists through clinical specialists to end up pioneers in exploration on lipid digestion system and its connection to cardiovascular sickness, diabetes, weight, atherosclerosis, metabolic disorders, immunological illnesses, and disease and so forth.

The Injectable Drug Delivery Market by Formulation (Liposomes, Nanoparticles and Microspheres), Devices and Therapeutics [Diabetes and Oncology] - Global Forecasts to 2017, dissects and contemplates the real market drivers, restrictions, and chances in North America, Europe, Asia-Pacific, and Rest of the World. Worldwide injectable medication conveyance advancements market over the gauge time of 2012 to 2017. The worldwide injectable medication conveyance advancements business sector was esteemed at $22.5 billion in 2012; it is relied upon to reach $43.3 billion by 2017 at a CAGR of 14.0% from 2012 to 2017. Injectable medication conveyance advancements are the mix of two noteworthy portions; gadgets and definitions. This business sector understanding report on Liposomes gives knowledge into worldwide Liposomes market. The concentrate additionally gives data with respect to items and innovations in the field of Liposomes. Business profiles of 46 noteworthy organizations are examined in the report. The report covers more than 330 organizations that are occupied with Liposomes research and supply of items and/or administrations. The worldwide liposomes' business sector is anticipated at a CAGR of 15%, through 2005-2015.

Clinical drugs that connect with membrane lipids and that modify the composition and structure of cell membranes can transform the localization and/or activity of membrane proteins. In general, adjustments in membrane lipid structure are emulated in changes in membrane lipid activity. Several drugs used to fight against cancer, cardiovascular diseases and obesity and other pathologies, determine lipid structure in plasma membrane and they produce a concomitant alteration in the localization and activity of signaling proteins. The recent studies have resulted in identifying specific disease-provoking gene mutations and have led to improved clinical and laboratory treatments, prenatal diagnosis in lipid related diseases.

The total cost of reducing low-density lipoprotein includes the costs of physician services, lifestyle counseling, screening, case finding and monitoring, dietary and exercise modifications, medications, and treating side effects. The annual cost of statin drugs to reduce low-density lipoprotein cholesterol levels can range from $1,082 to $1,543 per year. The cost of follow-up or treatment-related appointments varies by type of provider, location, and practice setting. Although the cost of reducing low-density lipoprotein cholesterol levels can be high, it is much lower than the direct and indirect costs of cardiovascular disease research.

Hyperlipoproteinemia is the lipid unsettling influence of significant pertinence clinically as a result of its link with an enlarged danger of atherosclerotic cardiovascular sickness. Hoisted plasma triglycerides and low-thickness lipoproteins are specifically connected with the danger of atherosclerotic coronary illness, in spite of the fact that not as free hazard variables. Interestingly, abnormal states of high-thickness lipoprotein cholesterol have been observed to be a defensive component for the advancement of that infection, so that diminished levels constitute a danger element. Atherosclerosis is described by vascular impediment from the stores of plaque, bringing about diminished blood stream. Plaque crack and the subsequent thrombosis might prompt sudden blockage of the corridors and cause heart assault. Plasma lipoproteins have generally been gathered into five noteworthy classes, in light of their light density: chylomicrons, low-thickness lipoproteins (VLDL), halfway thickness lipoproteins (IDL), low-thickness lipoproteins (LDL), and high-thickness lipoproteins (HDL). Since lipids are not solvent in blood, they are transported as lipoproteins after response with water-dissolvable proteins in the blood. Lipids in the blood are consumed by liver cells to give vitality to cell capacities. Overabundance lipids in the blood are in the long run changed over into fat tissue. Unusually elevated amounts of triglycerides and cholesterol are speculated to be involved in solidifying of the corridors. In nondiabetic persons of ordinary weight, organization of insulin prompts an expansion in glucose up-take by insulin-delicate tissues, hindrance of lipolysis, and a reduction in serum levels of free unsaturated fats. Be that as it may, in insulin-safe states joined by hyperinsulinemia, for example, happen in heftiness and type II diabetes, there is imperviousness to brings about expanded fat breakdown and expanded serum levels of free unsaturated fats and glycerol. The expanded glycerol coming about because of lipolysis tends to drive gluconeogenesis by mass impact, along these lines prompting expanded glucose generation by the liver, further adding to hyperglycemia. Lipid stockpiling ailments are a gathering of acquired metabolic disorder in which hurtful measures of greasy materials (lipids) amass in different tissues and cells in the body. Lipid stockpiling ailments are acquired from one or both folks who convey an imperfect quality.

An individual lipid particle will stay in the annular shell around a protein for just a brief timeframe. Tying to the annular shell indicates generally minimal auxiliary specificity. And the annular lipid, there is proof for other lipid atoms bound between the transmembrane alpha-helices of the protein; these lipids are alluded to as non-annular lipids. Voltage-gated channels are key transducers of film potential changes into intracellular homeless people that start numerous physiological occasions. The conformational change mutilates the state of the channel proteins adequately such that the depression, or channel, opens to concede particle flood or efflux to happen over the layer, down its electrochemical angle.

Lipid microarrays will give an incorporated learning base to the human lipidome. Exogenous fat is transported in chylomicrons from the digestive system to the liver. After passage in the circulatory system the chylomicrons are hydrolyzed by the endothelial-enslaved lipoprotein lipase. The chylomicron leftovers are quickly taken up into the liver by means of the LDL receptor and the LDL receptor-linked protein. Apolipoprotein E and lipoprotein lipase are the acknowledgment signals for these receptors. The liver uses the exogenous fat and can discharge surplus lipids by means of VLDL into the blood. The remaining VLDL leftovers can either be taken up into the liver or are hydrolyzed to LDL. Both these types of Hypercholesterolemia are the most successive and speak to significant danger elements for arteriosclerosis.

Today 66% of grown-ups and about 33% of youngsters battle with overweight and obesity. If heftiness rates stay reliable, by 2030, 51 percent of the populace will be obese. Twenty years prior, no state had a stoutness rate above 15 percent. Today there are 41 states with stoutness rates more than 25 percent, as indicated by the Trust for Europe’s Health. Following 1980, the rate of weight in kids and young people has practically tripled. 72% of more established men and 67% of more seasoned ladies are currently overweight or stout. Heftiness is connected to more than 60 perpetual illnesses. By European Association for the Study of Obesity, 482,000 Europeans kick the bucket of tumor every year, around 33% of these growth passings are connected to overabundance body weight, poor sustenance and/or physical idleness. More than 75 percent of hypertension cases are specifically connected to stoutness. Roughly 66% of Europe grown-ups with sort 2 diabetes are overweight or have heftiness.

Understanding the mechanisms of intracellular trafficking and its interaction with other signaling molecules may lead to novel approaches in the treatment of a number of hematologic and other diseases. NIH has invested $127,980 in this specific area in 2015.

Lipid rafts/caveolae flagon formed structures are rich in proteins and additionally lipids, for example, cholesterol and sphingolipids and have a few capacities in signal transduction. They assume a part in disease cells advancement, endocytosis and the uptake of pathogenic microorganisms and certain infections. Ponders that have illustrated the part of lipid pontoons in flagging by means of bioreceptor tyrosine kinases and G protein-coupled receptors. The inositol phospholipids frame the basic premise for a mind boggling interchange of flagging reactions created, most regularly, by receptor actuation and bringing about changes in Ca +2 , protein kinase falls, and particle channel/exchanger movement. Phosphatidylinositol (PI) itself is a negligible phospholipid constituent of all eukaryote plasma films.

Despite the fact that the plasma layer might contain microdomains with an assortment of various lipid creations, cholesterol and sphingolipid rich microdomains, named lipid flatboats, have been the most strongly examined. Flatboats are hypothesized to direct protein–protein interactions by horizontally isolating proteins as per their partiality for requested layer areas. New endeavours need to create and test elective theories for lipid-intervened natural capacity are basic to propelling our comprehension of plasma layer areas and their parts in cell capacity. Cholesterol is an amphipathic particle like phospholipid moiety. It contains a hydrophobic interactions and hydrophilic interactions. Regardless of its little mass, cholesterol assumes a critical part in keeping up the trustworthiness of the film and is likewise included with cell to cell flagging procedure.

Fossil fuels are the lifeblood of our society and for many others around the world. The environmental pollution due to the use of fossil fuels as well as their gradual depletion make it necessary to find alternative energy and chemical sources that are environmentally friendly and renewable. Waste lipids are ideal potential substrates for biogas production, since theoretically more methane can be produced, when compared with proteins or carbohydrates. Anaerobic bioconversion of complex organic matter to methane consists of a series of microbiological processes. First step involves the hydrolysis of complex organic polymers (proteins, carbohydrates and lipids) into monomers by extracellular enzymes that are excreted by fermentative bacteria. Proteins are degraded to amino acids, carbohydrates to soluble sugars and lipids to glycerol and LCFAs by the concerted action of proteases, cellulases and lipases respectively. Lipid hydrolysis is generally faster than protein or carbohydrate hydrolysis, and considered to be a rapid process in anaerobic digestion.

The economic burden of lipid disorders is substantial because of the impact of lipid levels on the risk of cardiovascular disease and coronary heart disease events. The direct and indirect costs of all types of cardiovascular disease in 2015 were estimated to be $706.2 billion. The cost of cardiovascular disease exceeds that of any other high-cost medical conditions. For example, in 2008, the estimated total cost of all cancers was $228 billion and in 2007, the cost attributable to diabetes mellitus was $174 billion.

The nature of fat is for the most part indicated by the relative substance of SFA, monounsaturated (MUFA), and polyunsaturated unsaturated fats (PUFA) including the extent or measure of vital unsaturated fats, that is, linoleic corrosive (LA) and α-linolenic corrosive (ALA),as well as the extent or measure of long-chain n-3 unsaturated fats (n-3 LCPUFA), that is, eicosapentaenoic corrosive (EPA) and docosahexaenoic corrosive (DHA). Coronary illness is perceived to be the reason for death for 80% of individuals with diabetes. Diabetes is treatable, however notwithstanding when glucose levels are under control it incredibly expands the danger of coronary illness and stroke. Hypertension has for quite some time been perceived as a noteworthy danger component for cardiovascular illness. Weight is a noteworthy danger element for cardiovascular disease and has been unequivocally connected with insulin resistance. Physical idleness is another modifiable real hazard component for insulin resistance and cardiovascular infection. Fish, plant, and nut oils are the essential dietary origin of omega-3 unsaturated fats. Eicosapentaenoic corrosive (EPA) and docosahexaenoic corrosive (DHA) are found in icy water fish, for example, salmon, mackerel, halibut, sardines, fish, and herring. Dietary admission of omega-3 unsaturated fats has declined by 80% amid the most recent 100 years, while admission of omega-6 unsaturated fats has extraordinarily expanded. Omega-3 unsaturated fats are cardioprotective for the most part because of helpful impacts on arrhythmias, atherosclerosis, irritation, and thrombosis.

Lipids play diverse roles in the normal functioning of the body. They serve as the structural building material of all cell membranes and organelles. They provide energy for living organisms - providing more than twice the energy content compared with carbohydrates and proteins on a weight basis. They function as molecular messengers and signalling molecules in the body.

Lipids are also biomarkers of disease and are involved in several pathological conditions. Lipids are also known to play a role in genetic modification and inﬂuence risk of chronic disease.

Some of the fatty acids need to be taken in diet. This includes essential fatty acids (EFAs), linoleic acid (LA, an omega-6 fatty acid, 18:2n-6), and a-linolenic acid (LNA, an omega-3 fatty acid, 18:3n-3). These help in formation of polyunsaturated fatty acids (PUFAs) used in cellular structures and as precursors for the biosynthesis of many of the body’s regulatory molecules like long-chain PUFAs, arachidonic acid, eicosapentaenoic acid (EPA, 20:5n-3), and docosahexaenoic acid (DHA, 22:6n-3) and eicosanoids. DHA again is necessary for normal neural and retinal development in the infant and young child.

The fact that lipids are soluble in organic solvents, but insoluble in water, provides the food analyst with a convenient method of separating the lipid components in foods from water soluble components, such as proteins, carbohydrates and minerals. In fact, solvent extraction techniques are one of the most commonly used methods of isolating lipids from foods and of determining the total lipid content of foods.

The aim of all extraction procedures is to separate cellular or fluid lipids from the other constituents, proteins, polysaccharides, small molecules (amino acids, sugars...) but also to preserve these lipids for further analyses.

There is a great diversity of methodologies because biological tissues are not similar when considering their structure, texture, sensitivities and lipid contents. The ideal solvent for lipid extraction would completely extract all the lipid components from a sample, while leaving all the other components behind. In practice, the efficiency of solvent extraction depends on the polarity of the lipids present compared to that of the solvent.

Polar lipids (such as glycolipids or phospholipids) are more soluble in polar solvents (such as alcohols), than in non-polar solvents (such as hexane). On the other hand, non-polar lipids (such as triacylglycerols) are more soluble in non-polar solvents than in polar ones. The fact that different lipids have different polarities means that it is impossible to select a single organic solvent to extract them all. Thus the total lipid content determined by solvent extraction depends on the nature of the organic solvent used to carry out the extraction: the total lipid content determined using one solvent may be different from that determined using another solvent.

The high sensitivity of the analytical methods needed for low amounts of extracted lipids requires the use of very pure solvents and clean glassware. The chemical nature of the extracted lipids must also be taken into consideration.

Lipids are a diverse and ubiquitous group of compounds which have many key biological functions, such as acting as structural components of cell membranes, serving as energy storage sources and participating in cell signaling pathways. Lipids may be broadly defined small molecules that originate entirely or in part from two distinct as hydrophobic or amphipathic types of biochemical subunits or "building blocks": ketoacyl and isoprene groups. The huge structural diversity found in lipids arises from the biosynthesis of various combinations of these building blocks. For example, glycerophospholipids are composed of a glycerol backbone linked to one of approximately 10 possible headgroups and also to 2 fatty acyl/alkyl chains, which in turn may have 30 or more different molecular structures. In practice, not all possible permutations are detected experimentally, due to chain preferences depending on the cell type and also to detection limits - nevertheless several hundred distinct glycerophospholipid molecular species have been detected in mammalian cells.

For years, reductionism derived from the "fluid mosaic" model of the cell membrane has portrayed membrane lipids as rather passive molecules that, whereas separating biologically relevant aqueous phases, provided an environment so that membrane proteins could fulfil the specificity and selectivity required for proper cell signaling. Whereas these roles for membrane lipids still stand, the structural diversity of lipids and their complex arrangement in supramolecular assemblies have expanded such limited, although fundamental roles. Growing developments in the field of membrane lipids help to understand biological phenomena at the nanoscale domain, and reveal this heterogeneous group of organic compounds as a long underestimated group of key regulatory molecules.

The role of oxidized lipids in cardiovascular diseases (CVD) has been investigated over the last three decades extensively. A number of studies have been carried out on the mechanisms, and pathways leading to the arterial atherosclerosis.

Lipid abnormalities play a critical role in the development of atherosclerosis.[3] Early experiments in animals demonstrated accelerated atherosclerosis with a high-cholesterol diet. This was followed by epidemiologic studies conducted in countries around the world that showed an increasing incidence of atherosclerosis when serum cholesterol concentrations were elevated.

Atherosclerosis is the leading cause of death in North America and within the next two decades will be the leading cause worldwide. Atherosclerosis is characterized by vascular obstruction from the deposits of plaque, resulting in reduced blood flow. Plaque rupture and the consequent thrombosis may lead to sudden blockage of the arteries and cause heart attack. High serum lipid levels, especially the elevated level of low-density lipoproteins (LDL), have been shown to be strongly related to the development of atherosclerosis. It is generally accepted that atherosclerotic lesions are initiated via an enhancement of LDL uptake by monocytes and macrophages. In the liver, uptake of plasma LDL is mediated via specific LDL receptors, but a scavenger receptor system is employed by macrophages. Plasma LDL must be modified prior to uptake by macrophages.

Essential oils have been used for more than 5,000 years. Their origin can be traced back to the ancient civilization of Mesopotamia. In later years the technology of obtaining these oils spread to Egypt, India, Greece and Rome. The most commonly used essential oils are lavender, chamomile, peppermint, tea tree oil, eucalyptus, geranium, jasmine, rose, lemon, orange, rosemary, frankincense, and sandalwood.

Most of the trade in essential oils occurs in the European Union (EU), the North American Free Trade Area (NAFTA), South America and East Asia with very little or insignificant trade happening in Africa and in particular the SADC region. Over the past two decades there has been an increase in the amount of overall trade (imports and exports) in essential oils, from about just over US$616-million in 1990 to more than US$3.6-billion in 2005. The EU has inherently been the largest trader of essential oils. In 2005 it imported US$536m and exported US$765m of US$1.7bn and US $1.9 bn world imports and exports, respectively. In the same period the north Atlantic free Trade Area (nAfTA) imported US$378m worth of imports and exported US$476m. SADC’s trade, which the main area of focus in this report is insignificant in the context of world trade – just about 1% overall. In 2005 exports and imports amounted to US$15.4m and US $25.8m, respectively. The opportunities for the region to increase its share in world trade are plenty. This is despite the fact that big established multinational corporations (i.e. end-users) have developed solid commercial relationship with suppliers that have a proven record of supplying high quality products.

Lipid Peroxidation by an unmistakable bit of UV light prompts an adjustment of the plant lipids. This change renders them solid inducers of heme oxygenase expression and blend of glutathione, the most important cellular cell reinforcement. Initiated lipid separates from plants prompt inborn cancer prevention agent and detoxificationpathways of skin cells. Most solid individuals can eat ALA from plant sources like chia and flaxseeds, and it will be changed into EPA and DHA. Just seven to 15 percent of the dietary ALA might be changed over to EPA. Considerably less is changed over to DHA. Furthermore, this is in a sound youngster. Soybean, canola, wheat germ and walnut oil all have a nice measure of omega-3's, yet much larger amounts of omega-6 unsaturated fats - and this proportion of omega-3's to omega-6's is imperative. Wellbeing specialists suggest an omega-6/omega-3 proportion of around 4:1.

The compartmentation of impartial lipids in plants is for the most part connected with seed tissues, where triacylglycerols (TAGs) put away inside lipid beads (LDs) serve as a key physiological vitality and carbon hold amid post germinative development. Be that as it may, some non-seed tissues, for example, leaves, blooms and natural products, additionally blend and store TAGs, yet moderately little is thought about the development or capacity of LDs in these tissues. Portrayal of LD-related proteins, for example, oleosins, caleosins, and sterol dehydrogenases (steroleosins), has uncovered astonishing components of LD capacity in plants, including cell stress reactions, hormone flagging pathways, and different parts of plant development and improvement. In spite of the fact that oleosin and caleosin proteins are particular to plants, LD-related sterol dehydrogenases likewise are available in well evolved creatures, and in both plants and warm blooded animals these compounds have been appeared to be imperative in (steroid) hormone digestion system and flagging. Also, a few different proteins known not essential in LD biogenesis in yeasts and vertebrates are preserved in plants, recommending that in any event a few parts of LD biogenesis and/or capacity are developmentally monitored.

In most plants storage lipids are in the form of triglycerides. There are a very few examples of alternative forms of storage lipid in higher plants. The most known of these is the desert shrub, jojoba, which stores its seed lipid as a liquid wax. Storage lipids may be accumulated in one or both of the main types of seed tissue, embryo or endosperm. In oilseeds such as sunflower, linseed or rapeseed, the cotyledons of the embryo are the major sites of lipid accumulation. In species such as castor bean, coriander or carrot, the endosperm is the main site of lipid accumulation.

Lipidomics has been incredibly encouraged by late advances in, and novel utilizations of, electrospray ionization mass spectrometry (ESI/MS. Lipidomic concentrates on assume a fundamental part in characterizing the biochemical metabolism of lipid-related sickness forms through distinguishing adjustments in cell lipid digestion system, trafficking and homeostasis. The two noteworthy stages at present utilized for lipidomic investigations are HPLC-MS and shotgun lipidomics. Late extension in exploration in the field of lipidomics has been driven by the advancement of new mass spectrometry and lipidomics devices and conventions for the distinguishing proof and measurement of sub-atomic lipids in complex networks. The utilization of electrospray ionization to unrefined lipid removes without earlier fractionation-the purported shotgun methodology is one such illustration, as it has maybe been more effectively connected in lipidomics than in some other Recent innovative advances in MS and chromatography have significantly upgraded the improvements and uses of metabolic profiling of various lipids in complex natural specimens. Lipidomics not just give experiences into the particular elements of lipid species in wellbeing and infection, yet will likewise distinguish potential biomarkers for building up preventive or restorative projects for human illness.

Market Analysis

Importance and Scope:

Lipid disorders are the broad term for abnormalities of cholesterol and triglycerides. Lipid abnormalities are associated with an increased risk for vascular disease, and especially heart attacks and strokes. Abnormalities in lipid disorders are a combination of genetic predisposition as well as the nature of dietary intake. Many lipid disorders are associated with being overweight. Lipid disorders may also be associated with other diseases including diabetes, the metabolic syndrome (sometimes called the insulin resistance syndrome). There is accumulating evidence that management of cholesterol and triglyceride disorders is associated with the reduced risk for heart attacks and strokes. This is especially true in patients seen by endocrinologists who have diabetes mellitus or other problems associated with obesity.

Elevated total cholesterol is most commonly a problem in patients who have elevated LDL cholesterol levels. Moderate elevations of LDL cholesterol are more common. These moderate elevations are still associated with heart disease risk. There are well established standards for what the targets of LDL cholesterol should be based on risk adjustment profiles. For example, young people with no heart disease risk factors have higher LDL cholesterol targets than patients who have diabetes or established heart disease.

Hypertriglyceridemia is associated with increased heart disease risk. Hypertriglyceridemia is commonly associated with obesity and diabetes mellitus. The medications used for treating triglycerides are often different than those used to lower LDL cholesterol. Treatment of contributors to high triglycerides including reduction in body weight and the management of diabetes mellitus are also important. Some medications used to lower blood sugar will also have a favorable effect on triglycerides. Isolated low cholesterol, low HDL cholesterol is quite uncommon. Most of the time low HDL cholesterol is associated with high triglycerides. It is well known that low HDL cholesterol contributes to heart disease risk. Exercise is important in helping to raise HDL cholesterol.

The metabolic syndrome is a term to describe patients who have central obesity, elevations of blood sugar (including diabetes), elevations in blood pressure as well as a lipid disorder characterized as high triglycerides, low HDL (and often mildly elevated LDL).

Abnormal lipid levels contribute to the development of cardiovascular diseases, including coronary heart disease, stroke, and coronary atherosclerosis. Coronary heart disease, which kills more Europeans than any other single disease, can lead to angina pectoris (heart pain), heart attack, or both. One European has a coronary attack about every 25 seconds, and about 34% of people who experience a coronary attack will die from it in any given year. At age 40, a man in the Europe has a 49% chance and a woman has a 32% chance of having a coronary heart disease event (such as a heart attack) in his or her lifetime.

Trends in a lipid measure vary across different countries; even in the same country different lipid measures might have different trends in both directions and magnitudes of changes. A number of studies have examined the trends in serum lipid levels either in repeated cross-sectional time-series or in longitudinal cohort studies. It seems that the trends in the levels of total and low density lipoprotein cholesterol (LDL-C) are favorable in most of countries, except India, China and Japan. In a global study of trends in serum total cholesterol in 199 countries, the mean level of total cholesterol changed little between 1980 and 2008, declining by less than 0.1 m mol/L per decade in men and women. Total cholesterol decreased in the high-income region consisting of Australasia, North America, and Western Europe, and in central and Eastern Europe while it increased in east and Southeast Asia and Pacific. In a previous report on time-trends in lipid measures among an Iranian adult population, we observed short-term favorable trends paralleling the increasing trend in obesity measures, whether such favorable trends have extended to a longer time-frame in the light of increases observed in the diabetes and obesity remains to be elucidated.

Recently the fourth follow-up assessment of a large community-based longitudinal study of a Middle East population, the Tehran Lipid and Glucose Study (TLGS) has been completed, herein, the trends in the population levels of serum lipids and indices as well as trends in prevalence of dyslipidemia among TLGS’ participants followed for more than a decade, enabling us to investigate the trends in lipid measures during the last decade.

Why Rome??

Depending on the Compound annual growth rate lipid disorders market Europe stands in second rank and next comes Asia. So the Lipids 2017 in going to be held in Rome, Italy.

Obesity has continued to grow within the Europe. Two out of every three Europeans are considered to be overweight or obese. During the early 21st century, Europe often contained the highest percentage of obese people in the world. Obesity has led to over 120,000 preventable deaths each year in the Europe. An obese person in Europe incurs an average of $1,429 more in medical expenses annually. Approximately $147 billion is spent in added medical expenses per year within the Europe.

Conference Highlights:

Lipids in Molecular Medicine

Lipid and Lipoprotein Metabolism

Protein-Lipid and Lipid-Lipid Interactions

Obesity and Health

Lipids in Signaling and Intracellular Trafficking

Lipids and Bioenergy

Fats - Cardio metabolic risks

Lipids: Nutrition and Health

Techniques Involved in Lipid Research

Structural Diversity of Lipids

Lipids in Atherosclerosis

Plant, Microbial lipids, Essential Oils – Future vision

Lipids in Plant Research

Lipidomics - What’s next?

Why to attend?

Lipids 2017 could be an exceptional event that brings along a novel and International mixture of giant and medium lipid research analysis, leading universities and Companies establishments creating the conference an ideal platform to share expertise, foster collaborations across trade and world, and assess rising technologies across the world. World-renowned speakers, the most recent techniques, tactics, and the newest updates in the field of lipids science and Novel treatment methods for CVD’s and Obesity are hallmarks of this conference.

A Unique Opportunity for Advertisers and Sponsors at this International event:

International Federation for the Surgery of Obesity and Metabolic Disorders

German Atherosclerosis Society

Italian Society for the Study of Atherosclerosis (SISA)

Austrian Diabetes Society

Croatian Association Diabetes

Finnish Diabetes Association

Diabetes Ireland

Lithuanian Diabetes Association

The Luxembourg Diabetes Association

Maltese Diabetes Association

Swiss Diabetes Foundation

Swedish Diabetes Association

Association for the Protection of Diabetics of Portugal

Polish Diabetes Association

The Norwegian Diabetes Association

International Diabetes Federation

Estonian Diabetes Association

Society for Endocrinology

International Society of Endocrinology

European Atherosclerosis Society

European Association for the Study of Diabetes (EASD)

European Foundation for the Study of Diabetes (EFSD)

Lipidomics and Nutrition Research Centre

European Federation for Clinical Chemistry and Laboratory Medicine

Spanish Society for Clinical Biochemistry and Molecular Pathology

Royal Free Hospital

Metabolic Clinic Ltd Spire Cardiff Hospital

Across the world:

International Society for the Study of Fatty Acids and Lipids (ISSFAL)

Lipid Association of India (LAI)

National Lipid Association

Philippine Lipid & Atherosclerosis Society

International Atherosclerosis Society

Endocrine Society

American Oil Chemists' Society

Canadian Cardiovascular Society

American Society for Nutrition

Biophysical Society

American Society for Biochemistry and Molecular Biology (ASBMB)

The Korean Society of Cardiology

American Skin Association

Australian Atherosclerosis Society

American Diabetes Association

Baker Heart and Diabetes Institute

British Dietetic Association

Canadian Obesity Network

Diabetes Australia

European Association for the Study of Diabetes

The Obesity Society

International Federation for the Surgery of Obesity and Metabolic Disorders

Diabetic Foot Society of India

UConn Rudd Center for Food Policy & Obesity

Stop obesity alliance

Center for Diabetes & Endocrinology

Diabetes Association of Jamaica

The Nutrition Society

The Diabetes Association of the Republic of China (Taiwan)

The Endocrine Society of the Republic of China (Taiwan)

Chinese Taipei Diabetes Association

Diabetes Australia

Diabetes Canada

Korean Diabetes Association

Diabetes Philippines

Juvenile Diabetes Research Foundation

International Diabetes Federation

The Japan Diabetes Society

Diabetes Association

Estonian Diabetes Association

Society for Endocrinology

Korean Endocrine Society

International Society of Endocrinology

The Turkish Biochemical society

International Society of Hypertension

Pediatric Endocrine Society

The American Society for Biochemistry and Molecular Biology

Australian Society Biochemistry and Molecular Biology

International Federation of Clinical Chemistry and Laboratory Medicine

American Society for Metabolism and bariatric Surgery

National Institute of Neurological Disorders and Stroke

International Association for the Study of Obesity

American Diabetes Association

International Association for the Study of Obesity

National Heart, Lung, and Blood Institute of the National Institutes of Health

Statistics:

Economic Burden of Condition/Disease in Europe:

The economic burden of lipid disorders is substantial because of the impact of lipid levels on the risk of cardiovascular disease and coronary heart disease events. The direct and indirect costs of all types of cardiovascular disease in 2015 were estimated to be $706.2 billion. The cost of cardiovascular disease exceeds that of any other high-cost medical conditions. For example, in 2008, the estimated total cost of all cancers was $228 billion and in 2007, the cost attributable to diabetes mellitus was $174 billion.

Heart disease and stroke are not only a major cause of premature death in persons younger than 65 years but also are major causes of serious disability in the United States. The indirect costs of cardiovascular disease, including those related to lost productivity, are enormous. It is estimated that the indirect cost of cardiovascular disease will total more than $279.1 billion in 2014.

The cost of implementing a lipid screening program varies by location, provider base, method of screening, which cholesterol measurements are taken, and other factors. The average cost of a single cholesterol or lipid profile test is relatively low but the cumulative costs of screening can be substantial, especially if all recommended screening and follow-up procedures are followed. In 2008, the private-sector cost of annual visits to lower LDL cholesterol averaged $74 per session.

Estimated Cost of Counseling and Treatment:

The total cost of reducing low-density lipoprotein includes the costs of physician services, lifestyle counseling, screening, case finding and monitoring, dietary and exercise modifications, medications, and treating side effects. The annual cost of statin drugs to reduce low-density lipoprotein cholesterol levels can range from $1,082 to $1,543 per year. The cost of follow-up or treatment-related appointments varies by type of provider, location, and practice setting. Although the cost of reducing low-density lipoprotein cholesterol levels can be high, it is much lower than the direct and indirect costs of cardiovascular disease.

In 2002, the National Cholesterol Education Program (NCEP) panel found that, on the basis of current retail prices for lipid-lowering drugs, low-density lipoprotein-lowering drug therapy is highly cost-effective for persons with established coronary heart disease (including a prior coronary heart disease event); cost-effective for the primary prevention of coronary heart disease in persons with a coronary heart disease risk equivalent (the person does not have coronary heart disease but does have an absolute 10-year risk of developing major coronary events, such as myocardial infarction and coronary death, equal to that of persons with coronary heart disease), and those at high risk for coronary heart disease; and acceptable for the primary prevention of coronary heart disease in persons whose 10-year risk of "hard coronary heart disease" (heart attack and death from coronary heart disease) is between 10% and 20%.

The National Cholesterol Education Program recommends using dietary therapy, which is more cost-effective than low-density lipoprotein-lowering drugs, as the first-line therapy in persons with a 10-year risk of coronary heart disease that is less than 10% per year.

Preventive Intervention Information:

Purpose of Screening, Counseling, and Treatment:

Screening for lipid disorders allows patients and clinicians to begin lipid-lowering treatment before cardiovascular disease develops or progresses. Most patients agree to be screened for lipid disorders, even when the screening involves fasting.

Benefits and Risks of Intervention:

Clinical trials have shown that reducing low-density lipoprotein levels reduces coronary heart disease risk, but the benefits of increasing high-density lipoprotein levels have not yet been fully demonstrated. In short-term clinical trials, a 1% reduction in low-density lipoprotein cholesterol levels, on average, reduced the risk of hard coronary heart disease events by about 1%. Persons who take low-density lipoprotein cholesterol-lowering drugs for about 5 years reduce their low-density lipoprotein levels by approximately 30% and decrease their risk of cardiovascular disease, including heart attacks, by about 30%. However, only about half of those who would benefit from lipid treatment receive it.

In persons with established coronary heart disease, low-density lipoprotein-lowering therapy reduces risk of stroke by about 30%. Statin therapy for the primary and secondary prevention of cardiovascular disease can reduce adverse cardiovascular events (including heart attacks and strokes) by 32% among patients aged 65 and older. Primary prevention trials using statins have shown a significant reduction in coronary heart disease mortality, no increase in non-coronary heart disease mortality, and a strong trend toward lower overall mortality.

Target Audience:

Lipidologists

Scientists and Doctors

Healthcare Professionals

Pharmaceutical researchers

Biochemists

Clinical organizations

Educational institutes

Academic Professionals

Pharma Industries

Manufacturing Medical Devices Companies

Medical Colleges

Past Conference Report

Lipids 2016

Conference Series LLC takes a great pride in announcing the “2nd International Conference and Expo on Lipids: Metabolism, Nutrition & Health (Lipids 2016) which was held at Orlando, USA during 03-05 October, 2016.

Lipids 2016 witnessed an amalgamation of peerless speakers who enlightened the crowd with their knowledge and confabulated on various new-fangled topics related to the field of Lipidomics. The extremely illustrious conference hosted by Conference Series was marked with the attendance of young and brilliant researchers, business delegates and talented student communities representing more than 20 countries around the world.

The conference aimed a parallel rail with theme “Solving the Impetus of Innovations in Lipid World”. The meeting engrossed a vicinity of cognizant discussions on novel subjects like Lipid and Lipid Metabolism, Lipids in Molecular Medicine, Structural Diversity of Lipids, Lipids in Signaling and Intracellular Trafficking, Lipids: Nutrition and Health to mention a few. The three days event implanted a firm relation of upcoming strategies in the field of Lipids, Metabolism, Signalling and Intracellular Trafficking with the scientific community. The conceptual and applicable knowledge shared, will also foster organizational collaborations to nurture scientific accelerations.

The Organizing Committee would like to thank the moderators Dr. Marica Bakovic, University of Guelph, Canada and Dr. Cherryhan Salvedia, Misr International University, Egypt which resulted in smooth functioning of the conference.

The conference was embarked with an opening ceremony followed by a series of lectures delivered by both Honourable Guests and members of the Keynote forum. The highlights of the conference were the keynote forum by prominent scientists, T Colin Campbell, Cornell University and T. Colin Campbell Center for Nutrition Studies, USA; Edward A Dennis, University of California at San Diego, USA; Charles Hennekens, Charles E Schmidt College of Medicine, USA; Raj Lakshman, George Washington University, USA; gave their fruitful contributions in the form of highly informative presentations and made the conference a top notch one.

Conference Series is prerogative to thank the Organizing Committee Members, Keynote speakers, Chair and Co-chairs on transcribing the plenary sessions and workshops in a diversified and variegate manner to make this conference an enviable artefact.

Conference Series offers its heartfelt appreciation to the collaborators The Nutrition Society and Lipid Association of India who supported the conference in every aspect. We also express our sincere thanks to all the media partners for the promotion of our event to glory.

Conference Series thank Dr. George Kokotos, University of Athens, Greece who was our poster evaluator for his support.

We once again thank all the participants for their wonderful contribution towards the event which helped us for successful accomplishment of this event.

2nd International Conference and Expo on Lipids: Metabolism, Nutrition & Health would not have been successful if it has not been supported by international, multi-professional steering committee and coordination of the Journal of Glycomics & Lipidomics; Journal of Nutritional Disorders & Therapy; Bioenergetics: Open Access; and Journal of Plant Biochemistry & Physiology.

After the successful completion of two consecutive conferences we are overwhelmed to announce our next upcoming conferences which are going to be held in Europe “3rd International Conference on Lipid Science and Technology” which is going to be held during December 11-13, 2017 in Rome, Italy.

International conference on Lipid Science & Technology 2015, hosted by the OMICS Group was held during November 30- December 02, 2015 San Francisco, USA at DoubleTree by Hilton Hotel San Francisco Airport, San Francisco, USA with the theme “Solving the Impetus of Innovations in Lipid World”. Benevolent response and active participation was received from the Editorial Board Members of OMICS Group Journals as well as from the Scientists, Doctors, Professors, Nursing Lecturers, Nurses, Pharmaceutical Industries, Healthcare Industries, Researchers and Students from the fields Lipids 2015, who made this event successful.

The meeting was carried out through various sessions, in which the discussions were held on the following major scientific tracks:

Lipids in molecular medicine

Lipids in signaling and intracellular trafficking

Protein-Lipid & Lipid- Lipid interactions

Lipid and Lipoprotein Metabolism

Fats - cardio metabolic risks

Obesity and Health

Plant, Microbial lipids and Essential Oils

Lipids and bioenergy

Lipidomics - What’s next?

The conference was initiated with a series of lectures delivered by both Honorable Guests and members of the Keynote forum. The list included:

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